Enzymatic recycling of thermoplastic polyurethanes: Synergistic effect of an esterase and an amidase and recovery of building blocks.

Biological recycling of polyurethanes (PU) is a huge challenge to take up in order to reduce a large part of the environmental pollution from these materials. However, enzymatic depolymerization of PU still needs to be improved to propose valuable and green solutions. The present study aims to identify efficient PU degrading enzymes among a collection of 50 hydrolases. Screenings based on model molecules were performed leading to the selection of an efficient amidase (E4143) able to hydrolyze the urethane bond of a low molar mass molecule and an esterase (E3576) able to hydrolyze a waterborne polyester polyurethane dispersion. Degradation activities of the amidase, the esterase and a mix of these enzymes were then evaluated on four thermoplastic polyurethanes (TPU) specifically designed for this assay. The highest degradation was obtained on a polycaprolactone polyol-based polyurethane with weight loss of 33% after 51 days measured for the esterase. Deep cracks on the polymer surface observed by scanning electron microscopy and the presence of oligomers on the remaining TPU detected by size exclusion chromatography evidenced the polymer degradation. Mixing both enzymes led to an increased amount of urethane bonds hydrolysis of the polymer. 6-hydroxycaproic acid and 4,4'-methylene dianiline were recovered after depolymerization as hydrolysis products. Such building blocks could get a second life with the synthesis of new macromolecular architectures.

Draft genome sequence of Mesotoga strain PhosAC3, a mesophilic member of the bacterial order Thermotogales, isolated from a digestor treating phosphogypsum in Tunisia.

Mesotoga strain PhosAc3 was the first mesophilic cultivated member of the order Thermotogales. This genus currently contain two described species, M. prima and M. infera. Strain PhosAc3, isolated from a Tunisian digestor treating phosphogypsum, is phylogenetically closely related to M. prima strain MesG1.Ag.4.2(T). Strain PhosAc3 has a genome of 3.1 Mb with a G+C content of 45.2%. It contains 3,051 protein-coding genes of which 74.6% have their best reciprocal BLAST hit in the genome of the type species, strain MesG1.Ag.4.2(T). For this reason we propose to assign strain PhosAc3 as a novel ecotype of the Mesotoga prima species. However, in contrast with the M. prima type strain, (i) it does not ferment sugars but uses them only in the presence of elemental sulfur as terminal electron acceptor, (ii) it produces only acetate and CO2 from sugars, whereas strain MesG1.Ag.4.2(T) produces acetate, butyrate, isobutyrate, isovalerate, 2-methyl-butyrate and (iii) sulfides are also end products of the elemental sulfur reduction in theses growth conditions.

Cell-free protein-based enzyme discovery and protein-ligand interaction study.

Cell-free expression-based screening is sometimes more suitable than cell-based assays for enzyme discovery. The advantage of cell-free systems for expression of toxic, poorly expressed, or insoluble proteins has already been well documented. Cell-free methods can advantageously replace cell-based ones when screening has to be performed on cell lysates prepared from harvested cells, for instance, when dealing with protein-ligand interactions particularly when the latter is hydrophobic. From our experience, cell-free extracts efficient in both transcription and translation can be prepared from potentially any microorganism. Here we present a general method for preparation of cell-free extracts from prokaryotic and eukaryotic cells, selection of the best systems, and optimized conditions for specific protein expression. The method allows to select proteins for their ability to bind a selected target, to identify the inhibitors of such binding, or to identify novel enzymatic activities.

A quick in vitro pathway from prokaryotic genomic libraries to enzyme discovery.

Screening of prokaryotic genomes in order to identify enzymes with a desired catalytic activity can be performed in vivo in bacterial cells. We propose a strategy of in vitro expression screening of large prokaryotic genomic libraries based on Escherichia coli cell-free transcription-translation systems. Because cell-based expression may be limited by poor yield or protein misfolding, cell-free expression systems may be advantageous in permitting a more comprehensive screen under conditions optimized for the desired enzyme activity. However, monocistronic messages with an improved leader initiation context are typically used for protein production in vitro. Here, we describe successful use of a Pseudoalteromonas genomic DNA library for in vitro expression of DNA fragments carrying multiple open reading frames (ORFs) in the context of their authentic translation initiation sites and regulatory regions. We show that ORFs located far from the 5' and 3' ends of polycistronic transcripts can be expressed at a sufficient level in an in vitro transcription-translation system in order to allow functional screening. We demonstrate the overall cell-free functional screen strategy with the successful selection of an esterase from Pseudoalteromonas.

Characterization of a thermophilic DNA ligase from the archaeon Thermococcus fumicolans.

A PCR protocol was used to identify and sequence a gene encoding a DNA ligase from Thermococcus fumicolans (Tfu). The recombinant enzyme, expressed in Escherichia coli BL21(DE3) pLysS, was purified to homogeneity and characterized. The optimum temperature and pH of Tfu DNA ligase were 65 degrees C and 7.0, respectively. The optimum concentration of MgCl2, which is indispensable for the enzyme activity, was 2 mM. We showed that Tfu DNA ligase displayed nick joining and blunt-end ligation activity using either ATP or NAD+, as a cofactor. In addition, our results would suggest that Tfu DNA ligase is likely to use the same catalytic residues with the two cofactors. The ability for DNA ligases, to use either ATP or NAD+, as a cofactor, appears to be specific of DNA ligases from Thermococcales, an order of hyperthermophilic microorganisms that belongs to the euryarchaeotal branch of the archaea domain.